JP5932258B2 - Display device and control method thereof - Google Patents

Description

  The present invention relates to a display device and a control method thereof.

  A high-definition medical monitor (a display device for displaying a medical image) generally displays a medical image output from an external device such as a PC (personal computer). However, in the future, it is expected that a medical monitor capable of simply displaying a medical image with a single monitor will be developed with higher functionality of the medical monitor. Moreover, it is expected that a portable monitor (display device) will be developed as such a medical monitor. If such a medical monitor is used, normal interpretation is performed using a high-performance PC (software stored in the PC) and a monitor, and explanations to the patient are made using only the monitor (medical images are displayed). It is possible to do this by simply displaying the monitor alone. It is also expected that such a medical monitor will be connected to the network. Then, it is expected that a medical monitor that acquires and displays images from the network will be developed.

  In the case of the monitor as described above, it is necessary to match the appearance (display characteristics) of the displayed image with the target value. However, an image input from the PC (hereinafter referred to as an external input image) may change depending on characteristics of a graphic board provided in the PC and processing in the PC (for example, image processing performed in the PC). . That is, even with the same image, display characteristics may differ between an external input image and an image (single display image) displayed on a monitor alone. Therefore, as the display characteristic calibration, it is necessary to perform the display characteristic calibration of the external input image (hereinafter referred to as cooperative calibration) and the display characteristic calibration of the single display image (hereinafter referred to as single calibration).

Prior art relating to calibration is disclosed in, for example, Patent Documents 1 and 2.
Specifically, Patent Document 1 discloses a technique for correcting the result of soft calibration based on the result of device calibration. Soft calibration is performed based on data obtained by reading a printing result of a printer with a scanner. The device calibration is automatically performed in the printer, and is performed based on the potential of the latent image formed on the photosensitive drum and the density of the toner image.
Patent Document 2 discloses a technique in which light is measured by a light metering unit provided opposite to a liquid crystal display unit, and calibration is performed based on a difference value between a light metering result and a predetermined ideal value.

JP 2002-057911 A JP 2005-208548 A

However, even after the monitor performs the unit calibration and the linked calibration, the display characteristics of the external input image and the display characteristics of the unit display image may be different. For example, while the monitor (first monitor) is removed from the PC (first PC) and taken out, another user connects another monitor (second monitor) to the first PC, and the color of the image output by the first PC Etc. (output setting of the first PC) may be changed. If such a change is made, when the first monitor and the first PC are connected again and an image output from the first PC is displayed on the first monitor, the image (external input image) of the first monitor is displayed. The display characteristics are different from the display characteristics of the single display image of the first monitor. Further, when the PC connected to the first monitor is changed from the first PC connected at the time of executing the calibration to the second PC different from the first PC, the display characteristics of the external input image of the first monitor are It may be different from the display characteristics of a single display image of one monitor.

  An object of the present invention is to provide a technique capable of suppressing display characteristics from being different between an image based on an image signal input from an external device and an image displayed on a monitor alone.

The first display device of the present invention includes:
Measuring means for measuring the image displayed on the screen;
The first calibration image stored in advance is displayed, and single calibration is performed to adjust the display setting so that the measured value of the first calibration image measured by the measuring unit approaches the target value. First determining means for determining the first display setting;
A second calibration image based on a calibration image signal input from an external device is displayed, and displayed so that the measured value of the second calibration image measured by the measuring unit approaches the target value. A second determination means for determining a second display setting by executing linked calibration for adjusting the setting;
When displaying an external input image that is an image based on an image signal input from the external device, it is determined whether or not the output setting or the second display setting of the external device is different from the setting at the time of the previous external input image display. Determination means for performing ,
Have
The determination means displays a second calibration image with a second display setting when displaying an external input image, and the measured value of the second calibration image measured by the measurement means and the target When the difference from the value is larger than a predetermined threshold, it is determined that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display,
The second determining means executes the linkage calibration when the determining means determines that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display. Features.
The second display device of the present invention is
Measuring means for measuring the image displayed on the screen;
The first calibration image stored in advance is displayed, and single calibration is performed to adjust the display setting so that the measured value of the first calibration image measured by the measuring unit approaches the target value. First determining means for determining the first display setting;
A second calibration image based on a calibration image signal input from an external device is displayed, and displayed so that the measured value of the second calibration image measured by the measuring unit approaches the target value. Perform linked calibration to adjust settings
A second determining means for determining a second display setting;
When displaying an external input image that is an image based on an image signal input from the external device, it is determined whether or not the output setting or the second display setting of the external device is different from the setting at the time of the previous external input image display. Determination means for performing,
Have
When the external input image is displayed, the determination unit displays the second calibration image with the second display setting, and is displayed with the measured value of the second calibration image and the first display setting. When the difference between the measured value of the first calibration image and the measured value of the first calibration image is larger than a predetermined threshold, it is determined that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display,
The second determination unit executes cooperative calibration when the determination unit determines that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display.
It is characterized by that.
The third display device of the present invention is
Measuring means for measuring the image displayed on the screen;
The first calibration image stored in advance is displayed, and single calibration is performed to adjust the display setting so that the measured value of the first calibration image measured by the measuring unit approaches the target value. First determining means for determining the first display setting;
A second calibration image based on a calibration image signal input from an external device is displayed, and displayed so that the measured value of the second calibration image measured by the measuring unit approaches the target value. A second determination means for determining a second display setting by executing linked calibration for adjusting the setting;
Determination means for determining whether or not the second display setting is different from the setting at the time of the previous external input image display when displaying an external input image that is an image based on an image signal input from an external device;
Storage means for storing the past execution date and time of past single calibration and the past execution date and time of linked calibration;
Have
When the external input image is displayed, the determination unit determines that the second display setting is the previous external input image when the last execution date and time of the cooperative calibration is earlier than the last execution date and time of the unit calibration. It is determined that it is different from the display setting,
The second determination unit performs linked calibration when the determination unit determines that the second display setting is different from the setting at the time of the previous external input image display.
It is characterized by that.

The first display device control method of the present invention includes:
A measurement step for measuring the image displayed on the screen;
The first calibration image stored in advance is displayed, and single calibration is performed to adjust the display setting so that the measurement value of the first calibration image measured in the measurement step approaches the target value. A first determining step for determining a first display setting;
Display a second calibration image based on a calibration image signal input from an external device, and display setting so that the measurement value of the second calibration image measured in the measurement step approaches the target value A second determination step of determining a second display setting by executing linked calibration for adjusting
When displaying an external input image that is an image based on an image signal input from the external device, it is determined whether the output setting or the second display setting of the external device is different from the setting at the time of the previous external input image display. A determination step to:
Have
In the determination step, when the external input image is displayed, the second calibration image is displayed with the second display setting, and the measurement value of the second calibration image measured in the measurement step and the target When the difference from the value is larger than a predetermined threshold, it is determined that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display,
In the second determination step, when it is determined in the determination step that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display, linked calibration is executed. It is characterized by.
The control method of the second display device of the present invention is:
A measurement step for measuring the image displayed on the screen;
The first calibration image stored in advance is displayed, and single calibration is performed to adjust the display setting so that the measurement value of the first calibration image measured in the measurement step approaches the target value. A first determining step for determining a first display setting;
A second calibration image based on the calibration image signal input from the external device is displayed, and the measurement value of the second calibration image measured in the measurement step is displayed so as to approach the target value. A second determination step of determining a second display setting by executing linked calibration to adjust the setting;
When displaying an external input image that is an image based on an image signal input from the external device, it is determined whether or not the output setting or the second display setting of the external device is different from the setting at the time of the previous external input image display. A determination step for performing
Have
In the determination step, when the external input image is displayed, the second calibration image is displayed with the second display setting, and the measurement value of the second calibration image and the first display setting are displayed. When the difference between the measured value of the first calibration image and the measured value of the first calibration image is larger than a predetermined threshold, it is determined that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display,
In the second determination step, when the determination step determines that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display, linked calibration is executed.
It is characterized by that.
The third display device control method of the present invention includes:
A measurement step for measuring the image displayed on the screen;
The first calibration image stored in advance is displayed, and single calibration is performed to adjust the display setting so that the measurement value of the first calibration image measured in the measurement step approaches the target value. A first determining step for determining a first display setting;
A second calibration image based on the calibration image signal input from the external device is displayed, and the measurement value of the second calibration image measured in the measurement step is displayed so as to approach the target value. A second determination step of determining a second display setting by executing linked calibration to adjust the setting;
A determination step of determining whether or not the second display setting is different from the setting at the time of the previous external input image display when displaying an external input image that is an image based on an image signal input from an external device;
A storage step for storing the past execution date and time of the single unit calibration and the past execution date and time of the linked calibration;
Have
In the determination step, when the external input image is displayed, if the last execution date and time of the cooperative calibration is earlier than the last execution date and time of the unit calibration, the second display setting is the previous external input image. It is determined that it is different from the display setting,
In the second determination step, when it is determined in the determination step that the second display setting is different from the setting at the time of the previous external input image display, linked calibration is executed.
It is characterized by that.

ADVANTAGE OF THE INVENTION According to this invention, it can suppress that a display characteristic differs between the image based on the image signal input from the external apparatus, and the image displayed on a monitor single-piece | unit.

Example of display system according to embodiment 1 Example of hardware configuration of display device according to embodiment 1 Example of functional configuration of display device according to embodiment 1 Example of flow of calibration setting information setting processing according to embodiment 1 Example of setting window according to embodiment 1 An example of a normal calibration execution confirmation window according to the first embodiment Example of normal calibration flow according to embodiment 1 Example of single calibration flow according to embodiment 1 An example of the flow of cooperative calibration according to the first embodiment Example of selection signal switching processing according to the first embodiment Example of a flow of comparison processing by the display comparison unit according to the first embodiment Example of flow of non-ordinary cooperation calibration according to embodiment 1 Example of display image at the time of execution of calibration according to embodiment 1 Example of cooperative calibration execution confirmation window according to embodiment 1 Example of selection signal switching processing according to the second embodiment Example of flow of pre-switching data storage processing according to embodiment 2 An example of a flow of comparison processing by the display comparison unit according to the second embodiment Example of flow of non-ordinary cooperation calibration according to embodiment 2 Example of display system according to Embodiment 3 Example of relationship between time and PC connected according to embodiment 3 Example of functional configuration of display device according to embodiment 3 Example of selection signal switching processing according to the third embodiment Example of a flow of comparison processing by the display comparison unit according to the third embodiment

Hereinafter, a display device and a control method thereof according to an embodiment of the present invention will be described. The display device according to the present embodiment includes a measurement unit that measures an image displayed on the screen. In addition, the display device according to the present embodiment can execute unit calibration and linkage calibration.
The single calibration displays the first calibration image stored in advance in the display device, and adjusts the display setting so that the measurement value of the first calibration image measured by the measurement unit approaches the target value. Is.
Linked calibration displays a second calibration image based on a calibration image signal input from an external device so that the measurement value of the second calibration image measured by the measurement unit approaches the target value. The display setting is adjusted.
In the following, a case where the external device is a PC (personal computer) will be described, but the external device is not limited to this. The external device only needs to output an image signal to the display device, and may be, for example, a hard disk recorder, a Blu-ray recorder, a display device capable of external output, a game machine, or the like.
In the following, a case where the calibration image is a patch image will be described. However, the calibration image is not limited to a patch image. The calibration image may be, for example, a predetermined pattern image.

<Example 1>
FIG. 1 is a diagram illustrating an example of a display system according to Embodiment 1 of the present invention. As shown in FIG. 1, the display system according to the present embodiment includes a display device 100 (monitor), a PC 101, and an image server 103.
The display device 100 and the PC 101 are connected to each other using an image cable 102. The image cable 102 is, for example, a cable compliant with the DVI (registered trademark) or DisplayPort (registered trademark) standard, and is a cable capable of transmitting an image signal and a signal based on DDC / CI (Display Data Channel Command Interface). is there. The PC 101 connected to the display device 100 can be changed. That is, the external device that outputs an image signal to the display device 100 can be changed.
The display device 100 and the PC 101 are connected to the image server 103 using a network cable 104.

The display device 100 displays an image based on the input image signal or image file. For example, the display device 100 displays an image (external input image) based on the image signal output from the PC 101. Further, the display device 100 acquires an image file from the image server 103 based on a user operation, and displays an image (single display image) based on the acquired image file. Note that the communication between the display device 100 and the image server 103 is performed in accordance with a communication protocol that conforms to, for example, the DICOM (Digital Imaging Communications in Medicine) standard. The image file is, for example, an image file that conforms to the DICOM standard. Specifically, it is a compressed file compressed by a method such as JPEG, an uncompressed file such as a RAW file, or a lossless compressed file, etc., and metadata that complies with the DICOM standard is added. The display device decodes the acquired image file and displays an image based on the image file.
Further, the display device 100 transmits a control signal such as a patch transmission request signal to the PC 101. The patch transmission request signal is a signal indicating a request for transmission of a patch image signal (external patch signal).
In response to the patch transmission request signal from the display apparatus 100, the PC 101 transmits an external patch signal and a response signal such as a signal indicating completion of transmission of the external patch signal (patch transmission completion signal) to the display apparatus 100. . When the transmission of the external patch signal is completed, a patch image (external patch image; second calibration image) based on the external patch signal is completely displayed on the display device 100. Therefore, it can be said that the patch transmission completion signal is a signal indicating completion of display of the external patch image. Further, the PC 101 acquires an image file from the image server 103 based on a user operation. Note that communication between the PC 101 and the image server 103 is also performed in accordance with, for example, a communication protocol compliant with the DICOM standard. The PC 101 decodes the acquired image file to generate an image signal, performs predetermined processing as necessary, and outputs the image signal to the display device 100.

FIG. 2A is an example of a hardware block diagram of the display device 100. FIG. 2B is an image diagram showing an example of a cross section (cross section obtained by a plane perpendicular to the screen) in the vicinity of the luminance / chromaticity sensor 210 of the display device 100.
The CPU 201 reads a program for performing various controls from the nonvolatile memory 203 and controls each component block connected to the internal bus 213.
For example, the CPU 201 performs unit calibration and linkage calibration based on calibration setting information recorded in the nonvolatile memory 203. Details of the single unit calibration and the cooperation calibration will be described later. The calibration setting information is information including a calibration target value (maximum target luminance value, target gradation curve, etc.).
Further, when the calibration setting information is set by a user operation, the CPU 201 records (overwrites) the set calibration setting information in the nonvolatile memory 203. For example, the user operates the display device 100 using the touch panel 211.
The CPU 201 executes an image display application (such as an image viewer) based on a user operation.
Further, the CPU 201 acquires and decodes an image file from the image server 103 via the network communication circuit 212 based on a user operation on the image display application, and generates an image signal (single display image signal). Then, the CPU 201 applies image processing (window level adjustment or the like) to the generated single display image signal as necessary, and outputs the signal to the image processing circuit 205. Specifically, an image signal representing an image including an image based on the single display image signal (single display image) and an image of the image display application is generated and output to the image processing circuit 205.

The memory 202 temporarily stores data used for the processing of the CPU 201.
The nonvolatile memory 203 stores programs used by the CPU 201, backlight emission parameters, image quality adjustment parameters, calibration setting information, and the like. The backlight emission parameter is a backlight luminance value at the time of displaying an image. The image quality adjustment parameter is a look-up table used when the image processing circuit 205 performs image processing.
In this embodiment, the calibration of the display characteristics of the single display image (single calibration) and the calibration of the display characteristics of the external input image (cooperation calibration) are performed individually. For this reason, in this embodiment, two types of parameters for the single display image (first display setting) and the parameter for the external input image (second display setting) are determined as the backlight emission parameter and the image quality adjustment parameter. Recorded in the memory 203. Specifically, the single display image parameter is determined by executing the single calibration, and the external input image parameter is determined by executing the cooperative calibration.
Even if the original image file is the same for the single display image and the external input image, the signal of the external input image may be subjected to predetermined processing in the PC. The display characteristics of the external input image do not always match. Therefore, the display characteristics of the single display image and the external input image may not be matched only by executing the single calibration. This is why the unit calibration and the linkage calibration are executed in the present embodiment.

The image input circuit 204 receives an image signal (external input image signal (including an external patch signal)) from the PC 101 and outputs it to the image processing circuit 205. Further, the image input circuit 204 transmits a control signal to the PC 101 and outputs a response signal received from the PC 101 to the CPU 201.
The image processing circuit 205 applies image processing to the image signal received from the image input circuit 204 and the CPU 201 based on the image quality adjustment parameter recorded in the non-volatile memory 203, and the image signal to which the image processing is applied is liquid crystal. Output to the display device 206.

The liquid crystal display device 206 is a liquid crystal panel having a plurality of liquid crystal elements, and controls the transmittance of each liquid crystal element based on the image signal received from the image processing circuit 205.
The backlight control circuit 207 generates and outputs a backlight control signal for controlling the light emission luminance of the backlight 208 based on the backlight light emission parameter recorded in the nonvolatile memory 203.
The backlight 208 emits light based on the backlight control signal received from the backlight control circuit 207.
The light from the backlight 208 passes through the liquid crystal element of the liquid crystal display device 206, whereby an image is displayed.

The sensor control circuit 209 outputs a sensor control signal for controlling the luminance / chromaticity sensor 210 according to the measurement request signal received from the CPU 201, and outputs the luminance and chromaticity measured by the luminance / chromaticity sensor 210 to the CPU 201. To do. The measurement request signal is a signal indicating a request for measurement of luminance and chromaticity.
The luminance / chromaticity sensor 210 measures an image displayed on the screen. Specifically, brightness
The chromaticity sensor 210 starts measurement of luminance and chromaticity in response to receiving the sensor control signal from the sensor control circuit 209 and outputs the measurement result to the sensor control circuit 209. For example, as shown in FIG. 2B, the luminance / chromaticity sensor 210 is provided so as to face the screen (liquid crystal element), and the luminance and chromaticity on the screen (an image (patch displayed on the screen)). Measure the brightness and chromaticity of the image).

The touch panel 211 receives a user operation and notifies the CPU 201 of a signal corresponding to the user operation.
The network communication circuit 212 transmits an image transmission request signal to the image server 103 and acquires an image file.
Each component block of the liquid crystal display device 100 performs data communication via the internal bus 213.

FIG. 3 is a functional block diagram of the display device 100.
The UI unit 301 acquires current calibration setting information from the calibration setting management unit 302 when the user performs an operation for starting the setting of calibration setting information. Then, the UI unit 301 generates and outputs a window (setting window) signal for setting calibration setting information. Thereby, a setting window is displayed. Thereafter, when the user changes the calibration setting information as necessary and performs an operation to confirm the calibration setting information, the UI unit 301 outputs the confirmed calibration setting information to the calibration setting management unit 302. To do.
Also, the UI unit 301 outputs a normal calibration execution request signal to the calibration execution control unit 303 when the user performs an operation of executing calibration. The normal calibration execution request signal is a signal indicating a request for execution of normal calibration (both unit calibration and linked calibration).
Further, the UI unit 301 controls the single display image display control unit 312 to output a single display image signal to the display control unit 305 when the user performs an operation of displaying the single display image.
Further, the UI unit 301 outputs a switching request signal to the display control unit 305 in response to a user operation. The switching request signal is a signal indicating a request for switching the display image. In the present embodiment, in response to the switching request signal, the display image is a single display based on the external input image based on the external input image signal from the image input unit 308 and the single display image signal from the single display image display control unit 312. Switch between images. Note that the display image may be switched to an image other than the single display image and the external input image in response to the switching request signal.

  In response to a request from the UI unit 301, the calibration execution control unit 303, or the display comparison unit 311, the calibration setting management unit 302 reads the calibration setting information from the nonvolatile memory 203 and outputs it to the transmission source of the request. . Also, calibration setting information transmitted from the UI unit 301 is recorded (overwritten) in the nonvolatile memory 203.

The calibration execution control unit 303 determines the single display image parameter by executing the single calibration (first determination), and determines the external input image parameter by executing the linked calibration (second determination). ).
Specifically, the calibration execution control unit 303 acquires calibration setting information from the calibration setting management unit 302 in response to reception of a normal calibration execution request signal from the UI unit 301. Then, the calibration execution control unit 303 executes normal calibration (both unit calibration and linkage calibration).
In addition, the calibration execution control unit 303 executes cooperative calibration in response to reception of the cooperative calibration execution request signal from the display comparison unit 311.

  When executing the single calibration, the calibration execution control unit 303 outputs a patch signal (internal patch signal) stored in advance to the display control unit 305. Thereby, a patch image (internal patch image; first calibration image) based on the internal patch signal is displayed. At that time, the calibration execution control unit 303 outputs a measurement request signal to the color measurement unit 307. Then, the calibration execution control unit 303 acquires the measurement result of the luminance / chromaticity sensor 210 (the luminance and chromaticity of the displayed internal patch image) from the color measurement unit 307. Thereafter, the calibration execution control unit 303 calculates image quality adjustment parameters and backlight emission parameters based on the acquired luminance and chromaticity, and outputs them to the display control unit 305, the backlight control unit 306, and the parameter management unit 304. To do.

On the other hand, when executing cooperative calibration, the calibration execution control unit 303 outputs a patch transmission request signal to the PC communication unit 309. Thereby, an external patch signal is input from the PC 101 and an external patch image is displayed. At that time, the calibration execution control unit 303 outputs a measurement request signal to the color measurement unit 307. Then, as in the case of unit calibration, the calibration execution control unit 303 acquires the measurement result of the luminance / chromaticity sensor 210 (the luminance and chromaticity of the displayed external patch image) from the color measurement unit 307. Thereafter, the calibration execution control unit 303 calculates image quality adjustment parameters and backlight emission parameters based on the acquired luminance and chromaticity, and outputs them to the display control unit 305, the backlight control unit 306, and the parameter management unit 304. To do.
Details of the single unit calibration and the cooperation calibration will be described later.

The parameter management unit 304 writes the backlight emission parameter and the image quality adjustment parameter received from the calibration execution control unit 303 in the nonvolatile memory 203.
The display control unit 305 selects either the external input image signal output from the image input unit 308 or the single display image signal output from the single display image display control unit 312 according to the switching request signal, and selects the selected image signal. Is output to the image processing circuit 205. At that time, the display control unit 305 outputs an instruction to use the image quality adjustment parameter corresponding to the selected image signal to the image processing circuit 205, and the backlight emission corresponding to the selected image signal to the backlight control unit 306. Output instructions for using parameters. Thereby, the selected image signal is corrected by the image processing circuit 205, and an image based on the corrected image signal is displayed.
Also, the display control unit 305 outputs a display comparison request signal to the display comparison unit 311 when the image to be selected is switched from the single display image signal to the external input image signal. The display comparison request signal is a signal indicating a request for comparison as to whether or not the luminance and chromaticity of the external patch image match the target value.
Further, the display control unit 305 generates a composite image signal by combining the signal of the setting window received from the UI unit 301 and the patch signal received from the calibration execution control unit 303 with the selected image signal, The image is output to the image processing circuit 205. The composite image signal is a signal representing an image obtained by combining an image based on the selected image signal and an image such as a setting window or a patch image.
Further, the display control unit 305 outputs the image quality adjustment parameter received from the calibration execution control unit 303 during the execution of calibration to the image processing circuit 205.

  The backlight control unit 306 outputs the parameter switching instruction (instruction to use the backlight emission parameter corresponding to the image signal selected by the display control unit 305) received from the display control unit 305 to the backlight control circuit 207. Further, the backlight control unit 306 outputs the backlight emission parameter received from the calibration execution control unit 303 during calibration to the backlight control circuit 207.

The color measurement unit 307 outputs the measurement request signal received from the calibration execution control unit 303 or the display comparison unit 311 to the sensor control circuit 209. Further, the colorimetric unit 307 acquires the measurement result (luminance and chromaticity) of the luminance / chromaticity sensor 210 from the sensor control circuit 209 in response to a request from the calibration execution control unit 303 or the display comparison unit 311. Output to the request source.
The image input unit 308 outputs the external input image signal received by the image input circuit 204 from the PC 101 to the display control unit 305. The image input unit 308 outputs an input detection signal to the input presence / absence detection unit 310 when an external input image signal from the PC 101 is detected. When the image input unit 308 no longer detects an external input image signal from the PC 101, the image input unit 308 outputs an input cancellation signal to the input presence / absence detection unit 310.

When the patch transmission request signal is transmitted from the calibration execution control unit 303 or the display comparison unit 311, the PC communication unit 309 outputs the patch transmission request signal to the PC 101 via the image input circuit 204. In addition, the PC communication unit 309 receives a patch transmission completion signal from the PC 101 via the image input circuit 204 and outputs it to the calibration execution control unit 303 or the display comparison unit 311 (the transmission source of the patch transmission request signal).
The input presence / absence detection unit 310 determines whether or not an external input image signal is input from the PC 101 based on the input detection signal and the input release signal received from the image input unit 308, and stores the determination result as input presence / absence information. Specifically, the input presence / absence detection unit 310 determines that there is an input of an external input image signal during a period from the reception of the input detection signal to the reception of the input cancellation signal, and the external input image signal is received in other periods. It is determined that there is no input image signal input. The input presence / absence detection unit 310 outputs input presence / absence information in response to a request from the calibration execution control unit 303.

When the external input image is displayed, the display comparison unit 311 uses the external device output setting (such as the contents of image processing performed in the external device) or the second display setting (external input image parameter) as the previous external input. It is determined whether or not the setting is different from the setting at the time of image display.
Specifically, the display comparison unit 311 outputs a patch transmission request signal to the PC communication unit 309 in response to reception of the display comparison request signal from the display control unit 305. Thereby, an external patch signal is input from the PC 101 and an external patch image is displayed. At that time, the display comparison unit 311 outputs a measurement request signal to the color measurement unit 307. Then, the display comparison unit 311 acquires the measurement result of the luminance / chromaticity sensor 210 (the luminance and chromaticity of the displayed external patch image) from the color measurement unit 307. Thereafter, the display comparison unit 311 compares the measurement result with the calibration setting information (calibration target value) acquired from the calibration setting management unit 302. From the comparison, it is determined whether or not the output setting of the external device or the external input image parameter is different from the setting at the time of the previous external input image display. It is judged that there is.
When the display comparison unit 311 determines that it is necessary to execute the cooperation calibration, the display comparison unit 311 requests the calibration execution control unit 303 to execute the cooperation calibration. As described above, the calibration execution control unit 303 executes the cooperation calibration in response to the reception of the cooperation calibration execution request signal from the display comparison unit 311. In other words, in the present embodiment, the calibration execution control unit 303 determines that the display comparison unit 311 determines that the output setting of the external device or the external input image parameter is different from the setting at the time of the previous external input image display. Execute linked calibration.
Details of the determination processing of the display comparison unit 311 will be described later.

In response to an instruction from the UI unit 301, the single display image display control unit 312 outputs an image transmission request signal to the network communication unit 313 and acquires an image file from the network communication unit 313. Then, the single display image display control unit 312 decodes the acquired image file to generate a single display image signal, and the single display image signal is combined with an image signal such as an icon or the like as required by the user. The image processing is performed and output to the display control unit 305.
The network communication unit 313 transmits an image transmission request signal from the single display image display control unit 312 to the image server 103 via the network communication circuit 212 and acquires an image file from the image server 103. Then, the network communication unit 313 outputs the acquired image file to the single display image display control unit 312.

  The processing of each functional block (UI unit 301 to network communication unit 313) illustrated in FIG.

FIG. 4 is a flowchart illustrating an example of a flow of processing (calibration setting information setting processing) of the UI unit 301 when the user performs an operation for starting the setting of calibration setting information.
First, the UI unit 301 acquires current calibration setting information from the calibration setting management unit 302 (S401).

  Next, the UI unit 301 generates a setting window signal and outputs it to the display control unit 305 (S402). The display control unit 305 generates a composite image signal by combining the signal of the setting window with the signal of the currently displayed image, and outputs the composite image signal. Thereby, an image in which the setting window is superimposed on the currently displayed image is displayed.

  The user performs an operation of changing the calibration setting information (calibration target value) as necessary using the setting window, and then performs an operation of completing the setting of the calibration setting information (S403). . Although the details will be described later, in this embodiment, the setting window has an OK button and a cancel button, and when the user selects one of the two buttons, the setting of the calibration setting information is completed.

Next, the UI unit 301 deletes (closes) the setting window in response to selection of one of the two buttons (in response to an operation for completing the setting) (S404).
When the OK button is selected in S403 (S405: YES), the UI unit 301 outputs the set target value as calibration setting information to the calibration setting management unit 302 (S406). Thereby, the calibration setting information is saved (updated). Then, the UI unit 301 ends the process.
In addition, when the cancel button is selected in S403 (S405: NO), the UI unit 301 ends the process.

FIG. 5 is a diagram illustrating an example of the setting window.
The setting window 501 includes a text box 502, radio buttons 503 and 504, an OK button 505, a cancel button 506, and the like.

A text box 502 is a text box for setting a target maximum luminance value at the time of executing calibration. In the case of FIG. 5, the target maximum luminance value at the time of executing calibration is set to 300 cd / m ² .

  Radio buttons 503 and 504 are radio buttons for setting a target gradation curve at the time of calibration execution. When the radio button 503 is selected, the target gradation curve is set to DICOM GSDF, and when the radio button 504 is selected, the target gradation curve is set to γ2.2. In the case of FIG. 5, the target gradation curve is set to DICOM GSDF. The details of the target gradation curve are not the gist of the present invention, and thus the description thereof is omitted.

An OK button 505 and a cancel button 506 are buttons for completing the setting of calibration setting information.
When the OK button 505 is selected, the calibration setting information shown in the setting window is saved, and the setting of the calibration setting information is completed. At this time, the UI unit 301 is notified that the OK button has been selected.
When the cancel button 506 is selected, the setting of the calibration setting information is completed without saving the calibration setting information shown in the setting window. That is, when the setting of the calibration setting information is completed by selecting the cancel button 506, the change of the calibration setting information performed after displaying the setting window is invalidated. At this time, the UI unit 301 is notified that the cancel button has been selected (the OK button has not been selected).

  FIG. 6 is a diagram illustrating an example of a window (normal calibration execution confirmation window) displayed when the execution of normal calibration is started. In this embodiment, normal calibration is executed based on an instruction from the user. The normal calibration execution confirmation window is displayed, for example, when the user performs an operation for starting execution of calibration, or when the user performs an operation for completing the setting of calibration setting information. Specifically, the UI unit 301 generates a normal calibration execution confirmation window signal and outputs it to the display control unit 305 in response to a user operation. Thereby, a normal calibration execution confirmation window is displayed. In normal calibration, both single unit calibration and linked calibration are executed. However, when the external input image is not input to the display device 100 (when the external device (PC 101) is not connected to the display device 100), the cooperative calibration is not executed.

The execution confirmation window 601 includes an area 602 for displaying calibration setting information (target value), a yes button 603, a no button 604, and the like.
The user can check the current calibration setting information from the area 602.
The Yes button 603 is a button that the user presses (selects) to start normal calibration based on the calibration setting information displayed in the area 602. When the user selects the Yes button 603, a normal calibration execution request signal is output from the UI unit 301 to the calibration execution control unit 303. In the case of FIG. 6, execution of normal calibration is requested from the UI unit 301 to the calibration execution control unit 303 with a maximum target luminance value of 300 cd / m ² and a target gradation curve of DICOM GSDF.
A No button 604 is a button that the user presses (selects) in order not to perform normal calibration. When the user selects the No button 604, the execution confirmation window 601 is deleted (closed) without outputting the normal calibration execution request signal from the UI unit 301 to the calibration execution control unit 303.

FIG. 7 is a flowchart showing an example of the flow of normal calibration executed by the calibration execution control unit 303 in response to reception of the normal calibration execution request signal.
First, the calibration execution control unit 303 acquires calibration setting information from the calibration setting management unit 302 (S701).
Next, the calibration execution control unit 303 executes single unit calibration (S702). A flowchart of the single calibration will be described later.
The calibration execution control unit 303 acquires input presence / absence information from the input presence / absence detection unit 310 (S703).
When an external input image signal is input (S704: YES), the calibration execution control unit 303 continues to execute cooperative calibration (S705). A flowchart of the cooperation calibration will be described later. When the external input image signal is not input (S704: NO), the calibration execution control unit 303 ends the process without performing the cooperative calibration.

FIG. 8 is a flowchart illustrating an example of a single calibration flow by the calibration execution control unit 303.
First, the calibration execution control unit 303 requests the display control unit 305 to initialize image quality adjustment parameters, and requests the backlight control unit 306 to initialize backlight emission parameters (S801). As a result, the initial value of the parameter is used by the image processing circuit 205 and the backlight control circuit 207 when displaying an image.

Next, the calibration execution control unit 303 repeats the processes of S803 to S805 for the predetermined number of patch images (S802).
First, the calibration execution control unit 303 outputs an internal patch signal to the display control unit 305 (S803). The display control unit 305 generates and outputs a synthesized image signal by synthesizing the received internal patch signal with the signal of the currently displayed image. Thereby, an image in which the internal patch image is superimposed on the currently displayed image is displayed. At this time, the calibration execution control unit 303 outputs a measurement request signal to the color measurement unit 307. Thereby, the luminance / chromaticity sensor 210 measures the luminance and chromaticity of the internal patch image, and the measurement result is acquired by the colorimetric unit 307.
Next, the calibration execution control unit 303 acquires the luminance and chromaticity of the displayed internal patch image from the color measurement unit 307 (S804).
Then, the process returns to S802 (S805).

After the processes of S803 to S805 are repeated for the predetermined number of patch images, the process proceeds to S806.
In step S806, the calibration execution control unit 303 calculates image quality adjustment parameters and backlight emission parameters based on the acquired brightness and chromaticity of each patch image, maximum target brightness value, and target gradation curve.
Next, the calibration execution control unit 303 outputs the image quality adjustment parameter and the backlight emission parameter calculated in S806 to the display control unit 305 and the backlight control unit 306, respectively. Thereby, the parameter calculated in S806 is temporarily set, and an image is displayed using the temporarily set parameter (S807).

  Then, the calibration execution control unit 303 repeats the processes of S809 to S811 for the predetermined number of patch images (S808). Since the processing of S809 to S811 is the same as the processing of S803 to S805, the description thereof is omitted.

After the processes of S809 to S811 are repeated for a predetermined number of patch images, the process proceeds to S812.
In S812, the calibration execution control unit 303 evaluates the measurement results (luminance and chromaticity) acquired in S810. Specifically, the calibration execution control unit 303 determines that the brightness and chromaticity of each patch image acquired in S810 are a predetermined error with respect to the target value (maximum target brightness value, value based on the target gradation curve). It is determined whether it is within the range.

When all the measurement results of the patch images are within a predetermined error range with respect to the target value, the calibration execution control unit 303 determines that the single calibration is completed (S813: YES), and processing To S814. In S814, the calibration execution control unit 303 outputs the image quality adjustment parameter and the backlight emission parameter calculated in S806 to the parameter management unit 304, and records them as a single display image parameter.
When there is a measurement result that does not fall within a predetermined error range with respect to the target value, the calibration execution control unit 303 determines that it is necessary to continue the single calibration (S813: NO), and the process is performed in S815. Proceed to In step S815, the calibration execution control unit 303 finely adjusts the image quality adjustment parameter and the backlight emission parameter. Then, the process returns to S807. If there is a measurement result that does not fall within a predetermined error range with respect to the target value even if fine adjustment is performed a predetermined number of times or more, it is determined that the single unit calibration has been completed (S813: YES), and the process proceeds to S814. It is advanced.

FIG. 9 is a flowchart illustrating an example of the flow of linked calibration by the calibration execution control unit 303.
First, the calibration execution control unit 303 requests the display control unit 305 to display an external input image based on the external input image signal output from the image input unit 308 (S901). When receiving the request, the display control unit 305 selects and outputs the external input image signal output from the image input unit 308.

  Next, the calibration execution control unit 303 requests the display control unit 305 to initialize the image quality adjustment parameter, and the backlight control unit 306 sets the backlight emission parameter as in the case of the single unit calibration. Request for initialization (S902). As a result, the initial value of the parameter is used by the image processing circuit 205 and the backlight control circuit 207 when displaying an image.

Next, the calibration execution control unit 303 repeats the processing of S904 to S907 for a predetermined number of patch images (S903).
First, the calibration execution control unit 303 transmits a patch transmission request signal to the PC communication unit 309 (S904). As a result, a patch transmission request signal is transmitted from the PC communication unit 309 to the PC 101.
Next, the calibration execution control unit 303 waits until the image input unit 308 receives an external patch signal from the PC 101 and the PC communication unit 309 receives a patch transmission completion signal from the PC 101 (S905). When the reception of the external patch signal is completed, the PC communication unit 309 receives the patch transmission completion signal, and the PC communication unit 309 transmits the patch transmission completion signal to the calibration execution control unit 303. At this time, the external input image signal (including the external patch image) output from the image input unit 308 is selected in the display control unit 305 (by the processing of S901). Therefore, when an external patch signal is received from the PC 101, an external patch image based on the external patch signal output from the PC 101 is displayed on the screen.
When the calibration execution control unit 303 receives the patch transmission completion signal, the calibration execution control unit 303 outputs a measurement request signal to the color measurement unit 307. Thereby, the luminance / chromaticity sensor 210 measures the luminance and chromaticity of the external patch image, and the measurement result is acquired by the colorimetric unit 307. Then, the calibration execution control unit 303 acquires the luminance and chromaticity of the displayed external patch image from the color measurement unit 307 (S906).
Then, the process returns to S903 (S907).

After the processing of S904 to S907 is repeated for a predetermined number of patch images, the processing proceeds to S908.
In step S908, the calibration execution control unit 303 calculates image quality adjustment parameters and backlight emission parameters based on the acquired luminance and chromaticity, maximum target luminance value, and target gradation curve.
Next, the calibration execution control unit 303 outputs the image quality adjustment parameter and the backlight emission parameter calculated in S908 to the display control unit 305 and the backlight control unit 306, respectively. Thereby, the parameter calculated in S908 is temporarily set, and an image is displayed using the temporarily set parameter (S909).

  Then, the calibration execution control unit 303 repeats the processes of S911 to S914 for the predetermined number of patch images (S910). Since the process of S911-S914 is the same as the process of S904-S907, the description is abbreviate | omitted.

After the processes of S911 to S914 are repeated for a predetermined number of patch images, the process proceeds to S915.
In S915, the calibration execution control unit 303 evaluates the measurement results (luminance and chromaticity) acquired in S913. Specifically, the calibration execution control unit 303 determines that the brightness and chromaticity of each patch image acquired in S913 have a predetermined error with respect to the target value (maximum target brightness value, value based on the target tone curve). It is determined whether it is within the range.

When all the measurement results of the patch images are within a predetermined error range with respect to the target value, the calibration execution control unit 303 determines that the cooperative calibration is completed (S916: YES), and processing Advances to S917. In step S917, the calibration execution control unit 303 outputs the image quality adjustment parameter and the backlight emission parameter calculated in step S908 to the parameter management unit 304, and records them as external input image parameters.
When there is a patch image whose measurement result does not fall within a predetermined error range with respect to the target value, the calibration execution control unit 303 determines that it is necessary to continue the linked calibration (S916: NO), The process proceeds to S918. In step S918, the calibration execution control unit 303 finely adjusts the image quality adjustment parameter and the backlight emission parameter. Then, the process returns to S909. If there is a patch image in which the measurement result does not fall within a predetermined error range with respect to the target value even if fine adjustment is performed a predetermined number of times or more, it is determined that cooperative calibration has been completed (S918: YES), and S917. The process proceeds.

  In this embodiment, it is determined that the calibration is completed when all the measurement results of the patch images are within a predetermined error range with respect to the target value. However, the present invention is not limited to this configuration. Absent. For example, if the number of measurement results falling within a predetermined error range with respect to the target value is equal to or greater than a predetermined number (more than a predetermined ratio for all measurement results), it is determined that calibration is complete. Also good.

FIG. 10 is a flowchart illustrating an example of a flow of processing (selection signal switching processing) of the display control unit 305 when a switching request signal is received from the UI unit 301 by a user operation.
First, the display control unit 305 transmits an image quality adjustment parameter switching instruction to the image processing circuit 205 so as to switch the image quality adjustment parameter to be used to the image quality adjustment parameter for the image after display switching (S1001). When receiving the image quality adjustment parameter switching instruction, the image processing circuit 205 reads the image quality adjustment parameter for the image after the display switching from the nonvolatile memory 203. As a result, the image processing circuit 205 executes image processing using the image quality adjustment parameter for the image after display switching.

  Next, the display control unit 305 outputs a backlight emission parameter switching instruction to the backlight control unit 306 so as to switch the backlight emission parameter to be used to the backlight emission parameter for the image after display switching. (S1002). The backlight control unit 306 outputs the received backlight emission parameter switching instruction to the backlight control circuit 207. When receiving the backlight emission parameter switching instruction, the backlight control circuit 207 reads the backlight emission parameter for the image after the display switching from the nonvolatile memory 203. As a result, the backlight control circuit 207 generates a backlight control signal using the backlight emission parameter for the image after display switching.

Then, the display control unit 305 switches the image signal to be output based on the switching request signal (S1003).
Next, based on the switching request signal, the display control unit 305 determines whether the image displayed after switching is a single display image or an external input image (S1004).
If the image displayed after the switching is an external input image (S1005: YES), the display control unit 305 transmits a display comparison request signal to the display comparison unit 311 (S1006).
When the image displayed after switching is a single display image (S1005: NO), the display control unit 305 ends the process as it is.

FIG. 11 is a flowchart illustrating an example of a flow of processing (comparison processing) of the display comparison unit 311 when a display comparison request signal is received from the display control unit 305.
First, the display comparison unit 311 repeats the processing of S1102 to S1105 for a predetermined number of patch images (S1101).
In step S1102, the display comparison unit 311 transmits a patch transmission request signal to the PC communication unit 309. As a result, a patch transmission request signal is transmitted from the PC communication unit 309 to the PC 101.
Next, the display comparison unit 311 waits until the image input unit 308 receives an external patch signal from the PC 101 and the PC communication unit 309 receives a patch transmission completion signal from the PC 101 (S1103). When the reception of the external patch signal is completed, the patch transmission completion signal is received by the PC communication unit 309, and the patch transmission completion signal is transmitted from the PC communication unit 309 to the display comparison unit 311. At this time, the external input image signal (including the external patch image) output from the image input unit 308 is selected in the display control unit 305. Therefore, when an external patch signal is received from the PC 101, an external patch image based on the external patch signal output from the PC 101 is displayed on the screen as an external input image parameter.
When the display comparison unit 311 receives the patch transmission completion signal, the display comparison unit 311 outputs a measurement request signal to the color measurement unit 307. Thereby, the luminance / chromaticity sensor 210 measures the luminance and chromaticity of the external patch image, and the measurement result is acquired by the colorimetric unit 307. The display comparison unit 311 acquires the luminance and chromaticity of the displayed external patch image from the color measurement unit 307 (S1104).
Next, the process returns to S1101 (S1105).

After the processes of S1102 to S1105 are repeated for the predetermined number of patch images, the process proceeds to S1106.
In step S <b> 1106, the display comparison unit 311 acquires calibration setting information from the calibration setting management unit 302.
Next, the display comparison unit 311 calculates the theoretical values (target values) of luminance and chromaticity using the calibration setting information acquired in S1106 (S1107).
Then, the display comparison unit 311 compares the measurement result (luminance and chromaticity) acquired in S1104 with the theoretical value calculated in S1107 (S1108). By the comparison, it is determined whether or not the output setting of the external device or the external input image parameter is different from the setting at the time of the previous external input image display.
If there is a measurement result that does not fall within the predetermined error range with respect to the theoretical value (S1109: YES), the output setting of the external device or the parameter for the external input image is different from the setting at the time of the previous external input image display. Probability is high. Therefore, in this embodiment, in such a case, the display comparison unit 311 determines that the output setting of the external device or the external input image parameter is different from the setting at the time of the previous external input image display. Then, the display comparison unit 311 determines that it is necessary to execute cooperative calibration, and outputs a cooperative calibration execution request signal to the calibration execution control unit 303 (S1110).
When all the measurement results are within a predetermined error range with respect to the theoretical value (S1109: NO), the display comparison unit 311 indicates that the output setting of the external device or the external input image parameter is the previous external input. It determines with it being the same as the setting at the time of an image display, and complete | finishes a process as it is.

Thus, in this embodiment, when displaying an external input image, the external patch image is displayed with the second display setting (parameter for external input image). When the absolute value of the difference between the measured value of the external patch image measured by the luminance / chromaticity sensor 210 and the target value is larger than a predetermined threshold, the output setting of the external device or the external input image parameter is It is determined that the setting is different from the setting when the external input image is displayed.
In this embodiment, when there is a measurement result that does not fall within a predetermined error range with respect to the theoretical value, the output setting of the external device or the parameter for the external input image is the same as the setting at the time of the previous external input image display. Although determined to be different, it is not limited to this configuration. For example, when the number of measurement results that do not fall within a predetermined error range with respect to the target value is a predetermined number or more (a predetermined ratio or more for all measurement results), the output setting of the external device or the external input image It may be determined that the use parameter is different from the setting at the time of the previous external input image display.

FIG. 12 is a flowchart illustrating an example of a flow of processing (non-normal linkage calibration) of the calibration execution control unit 303 when a linkage calibration execution request signal is received from the display comparison unit 311.
First, the calibration execution control unit 303 requests the UI unit 301 to display a cooperative calibration execution confirmation window (S1201). In response to the request, the UI unit 301 generates a cooperation calibration execution confirmation window signal and outputs the signal to the display control unit 305. Thereby, a linked calibration execution confirmation window is displayed. The user selects whether or not to execute linked calibration using the linked calibration execution confirmation window.
Next, the calibration execution control unit 303 receives from the UI unit 301 a selection result as to whether or not to perform cooperative calibration by the user (S1202).
When the user selects execution of cooperative calibration (S1203: YES), the calibration execution control unit 303 acquires calibration setting information from the calibration setting management unit 302 (S1204). Then, the calibration execution control unit 303 executes the linked calibration shown in FIG. 9 using the maximum target luminance value and the target gradation curve included in the calibration setting information (S1205).
When the user selects non-execution of linked calibration (S1203: NO), the calibration execution control unit 303 waits for a certain time (S1206), and returns the process to S1201.

FIG. 13 is an image diagram of a display image of the display device 100 at the time of executing single calibration and cooperative calibration.
As shown in FIG. 13, when calibration is performed, a patch image P1301 is displayed near the luminance / chromaticity sensor 210, and the luminance and chromaticity of the patch image are measured by the luminance / chromaticity sensor 210.

FIG. 14 is a diagram illustrating an example of the cooperative calibration execution confirmation window.
The linked calibration execution confirmation window 1401 includes buttons 1402 and 1403 for selecting whether to execute linked calibration.
The user presses (selects) a button 1402 when selecting execution of linked calibration.
Further, the user presses (selects) a button 1403 when selecting non-execution of cooperative calibration.
The selection result (signal indicating the selected button) is input to the UI unit 301.

As described above, according to the present embodiment, when an external input image is displayed, the output setting of the external device or the second display setting (external input image parameter) is set at the time of the previous external input image display. It is determined whether or not. Then, when it is determined that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display, cooperative calibration is executed. For example, when the output setting of the external device connected to the display device is different from the setting at the time of the previous external input image display, or the external device connected to the display device was connected at the time of the previous external input image display Linkage calibration is executed when the device is different from the device. Thereby, it is possible to suppress the display characteristics from being different between an image based on an image signal input from an external device and an image displayed by a monitor alone.

  In this embodiment, the calibration target value is obtained from the maximum target luminance value and the target gradation curve, but the target value is obtained using other values such as color temperature. Also good. In addition, the target value at the time of executing the cooperative calibration is not the value acquired from the calibration setting information, but the result of the single calibration (the brightness and chromaticity of the internal patch image displayed by the single display image parameter) Also good.

The external patch signal may be an image signal representing only a patch image, or may be an image signal representing an image including an image area other than the patch image (including a patch image in a partial area). Good.
In this embodiment, the display image is switched to the external input image when executing the cooperative calibration. However, such a configuration is not necessary. For example, an image signal representing only the external patch image (or the external patch image and its vicinity) may be input to the display control unit 305 as in the case of executing the single unit calibration (the process of S702). Then, the display control unit 305 may generate and output a composite image signal by combining the input image signal and the signal of the currently displayed image. That is, an image in which the external patch image is superimposed on the currently displayed image (for example, a single display image) may be displayed without switching the display image.

  In the present embodiment, it is determined whether or not to perform the cooperation calibration when the user performs a switching operation of the display image to the external input image. However, such a configuration is not necessary. . When the input presence / absence detection unit 310 determines that an external input image signal is input, the display control unit 305 is instructed to switch the display image to the external input image, and the display image is automatically switched to the external input image. May be. Further, when the input presence / absence detection unit 310 determines that there is an input of an external input image signal, only the external patch image (or the external patch image and its vicinity) is superimposed on the currently displayed image, and linked calibration is performed. It may be determined whether or not to execute the operation. When only the external patch image is superimposed on the currently displayed image, the image is displayed using the external input image parameter.

In this embodiment, the normal calibration is executed by a user operation. However, the present invention is not limited to this configuration. Usually calibration may be performed automatically. For example, normal calibration may be performed periodically according to a predetermined schedule. The normal calibration may be executed in response to an instruction from an external device (such as the PC 101 or a server connected via a network).
When a schedule for executing calibration is determined in advance, a normal calibration execution confirmation window may be periodically displayed according to the schedule. Further, when an execution of calibration is instructed from an external device, a normal calibration execution confirmation window may be displayed in response to the instruction.

In this embodiment, when it is determined that the output setting or the second display setting of the external device is different from the setting at the time of the previous external input image display, the user is confirmed to execute or not execute the cooperation calibration. Although it was set as the structure, it is not restricted to this structure. When it is determined that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display, even if linked calibration is automatically executed without confirmation to the user Good.

In this embodiment, signals other than the image signal between the display device 100 and the PC 101 (patch transmission request signal and patch transmission completion signal) may be transmitted using a communication cable different from the image cable. For example, signals other than image signals may be transmitted using a USB (Universal Serial Bus) cable.
In this embodiment, the display device 100, the PC 101, and the image server 103 are connected to each other via the network cable 104. However, the display device 100, the PC 101, and the image server 103 may be connected so as to be able to communicate wirelessly. .
In this embodiment, an example in which the display device is a liquid crystal display device has been described. However, the display device is not limited to this. The display device may be an organic EL display device, a plasma display device, or the like.
In this embodiment, one external input image parameter is determined. However, the present invention is not limited to this configuration. An external device (PC) to which the display device 100 is connected may be recognized, and an external input image parameter may be determined for each external device.

<Example 2>
In this embodiment, an example is described in which the result of the unit calibration (the brightness and chromaticity of the internal patch image displayed with the parameters for the unit display image) is used as the target value of the cooperative calibration. In addition, description is abbreviate | omitted about the part which overlaps with Example 1. FIG.

A functional block diagram of a display device according to the second embodiment of the present invention is the same as that of the first embodiment (FIG. 3).
The calibration execution control unit 303 according to the present exemplary embodiment uses the measurement result of the internal patch image as a target value when performing the cooperative calibration in response to the cooperative calibration execution request signal from the display comparison unit 311. The calibration execution control unit 303 has other functions similar to those of the first embodiment.
The display control unit 305 of the present embodiment, when you switch the displayed image from the single display image to the external input image, outputs a switching pre-data acquisition request signal to the display comparing unit 311 before the switch, after the switching A display comparison request signal is output to the display comparison unit 311. The display control unit 305 has other functions similar to those of the first embodiment. The pre-switching data acquisition request signal is a signal for requesting acquisition of the luminance and chromaticity of the internal patch image displayed with the first display setting (single display image parameter).

In response to the reception of the pre-switching data acquisition request signal from the display control unit 305, the display comparison unit 311 according to the present embodiment outputs an internal patch signal stored in advance to the display control unit 305. Thereby, the internal patch image is displayed with the parameters for the single display image. At that time, the display comparison unit 311 outputs a measurement request signal to the color measurement unit 307. Then, the display comparison unit 311 acquires the measurement result (the luminance and chromaticity of the internal patch image) of the luminance / chromaticity sensor 210 from the color measurement unit 307 and stores the measurement result as pre-switching data. In addition, the display comparison unit 311 outputs the pre-switching data acquisition completion signal to the display control unit 305 after storing the pre-switching data.
Further, the display comparison unit 311 outputs a patch transmission request signal to the PC communication unit 309 in response to reception of the display comparison request signal from the display control unit 305. Thereby, an external patch signal is input from the PC 101 and an external patch image is displayed. At that time, the display comparison unit 311 outputs a measurement request signal to the color measurement unit 307. Then, the display comparison unit 311 acquires the measurement result (the luminance and chromaticity of the external patch image) of the luminance / chromaticity sensor 210 from the color measurement unit 307. Thereafter, the display comparison unit 311 compares the data before switching with the measurement result. From the comparison, it is determined whether or not the output setting of the external device or the external input image parameter is different from the setting at the time of the previous external input image display. It is judged that there is. When the display comparison unit 311 determines that it is necessary to execute the cooperation calibration, the display comparison unit 311 requests the calibration execution control unit 303 to execute the cooperation calibration.
Details of the determination processing of the display comparison unit 311 will be described later.

FIG. 15 is a flowchart illustrating an example of a flow of processing (selection signal switching processing) of the display control unit 305 when a switching request signal is received from the UI unit 301 by a user operation.
First, the display control unit 305 confirms whether the (currently) displayed image before switching is a single display image (S1701).
When the displayed image is a single display image (S1702: YES), the display control unit 305 transmits a data acquisition request signal before switching to the display comparison unit 311 (S1703), and a data acquisition completion signal before switching. (S1704). After receiving the pre-switching data acquisition completion signal, the display control unit 305 executes the process shown in FIG. 10 (S1705).
When the displayed image is an external input image, the display control unit 305 performs the process of S1705 without performing the processes of S1703 to S1704.

FIG. 16 is a flowchart illustrating an example of a flow of processing (data storage processing before switching) of the display comparison unit 311 when a data acquisition request signal before switching is received from the display control unit 305.
First, the display comparison unit 311 repeats the processing of S1802 to S1805 for the predetermined number of patch images (S1801).
In step S1802, the display comparison unit 311 outputs an internal patch signal to the display control unit 305. The display control unit 305 generates and outputs a synthesized image signal by synthesizing the received internal patch signal with the signal of the currently displayed image. Thereby, an image in which the internal patch image is superimposed on the currently displayed image is displayed. At this time, the display control unit 305 selects a single display image (signal). Therefore, the internal patch image is displayed using the single display image parameter. At this time, the display comparison unit 311 outputs a measurement request signal to the color measurement unit 307. Thereby, the luminance / chromaticity sensor 210 measures the luminance and chromaticity of the internal patch image, and the measurement result is acquired by the colorimetric unit 307.
Next, the display comparison unit 311 acquires the luminance and chromaticity of the displayed internal patch image from the color measurement unit 307 (S1803).
Then, the process returns to S1801 (S1804).

After the processing of S1802 to S1805 is repeated for a predetermined number of patch images, the display comparison unit 311 stores the acquired measurement results (luminance and chromaticity) as pre-switching data (S1805).
Then, the display comparison unit 311 transmits a pre-switch data acquisition completion signal to the display control unit 305 (S1806).

FIG. 17 is a flowchart illustrating an example of the flow of processing (comparison processing) of the display comparison unit 311 when a display comparison request signal is received from the display control unit 305.
First, the display comparison unit 311 repeats the processing of S1902 to S1905 for a predetermined number of patch images (S1901).
In step S1902, the display comparison unit 311 transmits a patch transmission request signal to the PC communication unit 309. As a result, a patch transmission request signal is transmitted from the PC communication unit 309 to the PC 101.
Next, the display comparison unit 311 waits until the image input unit 308 receives an external patch signal from the PC 101 and the PC communication unit 309 receives a patch transmission completion signal from the PC 101 (S1903). When the reception of the external patch signal is completed, the patch transmission completion signal is received by the PC communication unit 309, and the patch transmission completion signal is transmitted from the PC communication unit 309 to the display comparison unit 311. At this time, the external input image signal (including the external patch image) output from the image input unit 308 is selected in the display control unit 305. Therefore, when an external patch signal is received from the PC 101, an external patch image based on the external patch signal output from the PC 101 is displayed on the screen using the external input image parameter.
When the display comparison unit 311 receives the patch transmission completion signal, the display comparison unit 311 outputs a measurement request signal to the color measurement unit 307. Thereby, the luminance / chromaticity sensor 210 measures the luminance and chromaticity of the external patch image, and the measurement result is acquired by the colorimetric unit 307. Then, the display comparison unit 311 acquires the luminance and chromaticity of the displayed external patch image from the color measurement unit 307 (S1904).
Next, the process returns to S1901 (S1905).

After the processes of S1902 to S1905 are repeated for the predetermined number of patch images, the process proceeds to S1906.
In step S1906, the display comparison unit 311 acquires pre-switching data stored in the process of FIG.
Next, the display comparison unit 311 compares the measurement result (luminance and chromaticity) acquired in S1904 with the value of the data before switching acquired in S1906 (S1907). By the comparison, it is determined whether or not the output setting of the external device or the external input image parameter is different from the setting at the time of the previous external input image display. That is, in this embodiment, the value of the data before switching is set as the target value. When there is no pre-switching data, the measurement result is compared with a theoretically calculated target value as in the first embodiment.
When there is a measurement result that does not fall within the predetermined error range with respect to the value of the data before switching (S1908: YES), the display comparison unit 311 indicates that the output setting of the external device or the parameter for the external input image is It is determined that the setting is different from the setting at the time of external input image display. The display comparison unit 311 determines that it is necessary to execute cooperative calibration, and outputs a cooperative calibration execution request signal to the calibration execution control unit 303 (S1909).
If all the measurement results are within the predetermined error range with respect to the value of the data before switching (S1908: NO), the display comparison unit 311 indicates that the output setting of the external device or the parameter for the external input image is the previous time. It is determined that the setting is the same as that when the external input image is displayed. Then, the process is finished as it is.

Thus, in this embodiment, when displaying an external input image, the external patch image is displayed with the external input image parameter. When the absolute value of the difference between the specific value of the external patch image and the measured value of the internal patch image displayed by the single display image parameter is larger than a predetermined threshold, the output setting of the external device or the second It is determined that the display setting is different from the setting at the time of the previous external input image display. That is, in this embodiment, the internal patch image measured by the luminance / chromaticity sensor 210 while displaying the internal patch image stored in advance in the display device with the first display setting (parameter for single display image). The measured value is used as the target value.
In this embodiment, when the display image before switching is an external input image (that is, when the display image is not switched as a result), data before switching is not acquired. The configuration is not limited to this. The measurement result of the internal patch image may be acquired as pre-switching data regardless of the display image before switching. If the display image before switching is an external input image, the output setting of the external device and the external input image parameter are likely to be the desired settings. ) May not be performed.

FIG. 18 is a flowchart illustrating an example of the flow of processing (non-normal linkage calibration) of the calibration execution control unit 303 when a linkage calibration execution request signal is received from the display comparison unit 311.
First, the calibration execution control unit 303 requests the UI unit 301 to display a cooperative calibration execution confirmation window (S2001).
Next, the calibration execution control unit 303 receives a selection result as to whether or not to perform cooperative calibration by the user from the UI unit 301 (S2002).
When the user selects execution of cooperative calibration (S2003: YES), the calibration execution control unit 303 calculates the maximum target luminance value and the target curve from the pre-switch data (S2004). Then, the calibration execution control unit 303 executes the linked calibration shown in FIG. 9 using the calculated maximum target luminance and target curve (S2005).
When the user selects non-execution of cooperative calibration (S2003: NO), the calibration execution control unit 303 waits for a predetermined time (S2006), and returns the process to S2001.

As described above, according to the present embodiment, the internal patch image measured by the luminance / chromaticity sensor 210 is displayed while displaying the internal patch image stored in the display device in advance as a single display image parameter. The measured value is used as the target value. Since the target values of the cooperative calibration and the single calibration are the same, the result of the single calibration can be used as the target value. Therefore, according to the present embodiment, an effect according to the effect of the first embodiment can be obtained.
In this embodiment, the measurement result of the internal patch image is acquired when the display image is switched from the single display image to the external input image. However, the present invention is not limited to this configuration. For example, the measurement result of the internal patch image may be acquired at the time of executing the last unit calibration (when executing the last unit calibration). Further, the measurement result of the internal patch image may be acquired periodically.

<Example 3>
In the present embodiment, whether or not the second display setting (parameter for external input image) is different from the setting at the time of the previous external input image display based on the past execution date and time of single unit calibration and the execution date and time of linked calibration. An example of determining whether or not will be described. In other words, an example will be described in which it is determined whether or not to perform cooperative calibration based on the past execution date and time of single unit calibration and the execution date and time of cooperative calibration. In addition, description is abbreviate | omitted about the part which overlaps with Example 1,2.

  FIG. 19 is a diagram illustrating an example of a display system according to Embodiment 3 of the present invention. As already described, the external device (PC) connected to the display device can be changed. In the example of FIG. 19A, a PC 111 is connected to the display device 110 using an image cable 112. In the example of FIG. 19B, the display device 110 and the PC 111 are not connected, and the PC 113 is connected to the display device 110 using the image cable 114. The display device 110 acquires PC identification information from the PCs 111 and 113 via the image cables 112 and 114. The PC identification information is information for identifying a connected PC. The PC identification information of the PCs 111 and 113 is, for example, a value set by the user in the PCs 111 and 113 in advance.

FIG. 20 is a diagram illustrating an example of the relationship between the time and an external device (PC) connected to the display device 110. In the example of FIG. 20, the PC 111 is connected to the display device 110 from time t0 to time t1 and after time t4. The PC 113 is connected to the display device 110 from time t2 to time t3. From time t1 to time t2 and from time t3 to time t4, the PC is not connected to the display device 110, and the display device 110 operates alone. Note that the black triangle in FIG. 20 represents the time when the normal calibration is executed. That is, in the example of FIG. 20, both the single calibration and the cooperative calibration are performed at time t0 when the PC 111 is connected to the display device 110 and at time t2 when the PC 113 is connected to the display device 110. Further, the unit calibration is executed at time tc1 when the PC is not connected to the display device 110.

FIG. 21 is a functional block diagram of the display device 110 according to the present embodiment.
The calibration execution control unit 3203 executes linked calibration and determines the second display setting (external input image parameter) for each external device.
Specifically, the calibration execution control unit 3203 acquires PC identification information from the connected PC (PC 111 or PC 113) via the PC communication unit 3209 when executing the cooperative calibration. Then, the calibration execution control unit 3203 outputs the acquired PC identification information together when outputting the determined external input image parameter to the parameter management unit 3204 after executing the cooperative calibration.
In addition, the calibration execution control unit 3203 has the same function as the function of the calibration execution control unit 303 in FIG.

  The parameter management unit 3204 writes the input external input image parameters in the nonvolatile memory 203 in association with the PC identification information input together. In addition, when the parameter management unit 3204 writes the single display image parameter in the nonvolatile memory 203, the parameter management unit 3204 writes the writing time in the nonvolatile memory 203 as the execution date and time of the single calibration. When the parameter management unit 3204 writes the external input image parameter in the nonvolatile memory 203, the parameter management unit 3204 writes the writing time in the nonvolatile memory 203 as the execution date and time of the linked calibration. That is, the non-volatile memory 203 stores the past execution date and time of the past single calibration and the past execution date and time of the linked calibration. Further, with regard to the cooperation calibration, the past execution date and time of the cooperation calibration is stored for each external device. In addition, the parameter management unit 3204 has the same function as the function of the parameter management unit 304 of FIG.

  The display control unit 3205 acquires PC identification information via the PC communication unit 3209 and the input presence / absence detection unit 3210 when an external input image is selected. Then, the display control unit 3205 outputs an image quality adjustment parameter switching instruction to the image processing circuit 205 so that the image quality adjustment parameter corresponding to the PC identification information is used. Further, the display control unit 3205 outputs a backlight emission parameter switching instruction to the backlight control unit 306 so that the display comparison unit 3211 uses the backlight emission parameter corresponding to the PC identification information. The display control unit 3205 also outputs PC identification information when outputting a display comparison request signal to the display comparison unit 3211. In addition, the display control unit 3205 has the same function as the function of the display control unit 305 in FIG.

  The PC communication unit 3209 outputs a PC identification information acquisition request signal to an external device (PC 111 or PC 113) via the image input circuit 204 in response to requests from the calibration execution control unit 3203 and the input presence / absence detection unit 3210. When receiving the PC identification information acquisition request signal, the external device outputs its own PC identification information as a response signal. The PC communication unit 3209 acquires PC identification information from the PC 111 or PC 113 via the image input circuit 204 and outputs the PC identification information to the calibration execution control unit 3203 or the input presence / absence detection unit 3210 (request transmission source).

  Upon receiving an input detection signal from the image input unit 308, the input presence / absence detection unit 3210 acquires and stores PC identification information via the PC communication unit 3209. Besides, the input presence / absence detection unit 3210 has the same function as the function of the input presence / absence detection unit 310 of FIG.

When the display comparison unit 3211 receives the display comparison request signal and the PC identification information from the display control unit 3205, the display comparison unit 3211 acquires and compares the execution date / time of the single calibration and the execution date of the linked calibration from the parameter management unit 3204. Based on the comparison, it is determined whether or not the external input image parameter is different from the setting at the time of the previous external input image display. If it is determined that the external input image parameter is different, it is determined that it is necessary to perform cooperative calibration. If the display comparison unit 3211 determines that it is necessary to execute cooperative calibration, the display comparing unit 3211 requests the calibration execution control unit 3203 to execute cooperative calibration.
Details of the determination processing of the display comparison unit 3211 will be described later.

FIG. 22 is a flowchart illustrating an example of a flow of processing (selection signal switching processing) of the display control unit 3205 when a switching request signal is received from the UI unit 301 by a user operation.
First, the display control unit 3205 acquires PC identification information from the input presence / absence detection unit 3210 (S2401).

Next, the display control unit 3205 transmits an image quality adjustment parameter switching instruction to the image processing circuit 205 so as to switch the image quality adjustment parameter to be used to the image quality adjustment parameter corresponding to the image signal after the display switching (S2402). ). Specifically, when the image signal after display switching is an external input image signal, the display control unit 3205 identifies the PC that is the output source of the external input image signal from the PC identification information acquired in S2401. . For example, when the image signal after display switching is an external input image signal from the PC 113 , the display control unit 3205 uses the image quality adjustment parameter for the external input image signal input from the PC 113. In addition, an image quality adjustment parameter switching instruction is transmitted. Further, when the image signal after the display switching is a single display image signal, the display control unit 3205 transmits an image quality adjustment parameter switching instruction so that the image quality adjustment parameter for the single display image signal is used.

  Then, the display control unit 3205 transmits a backlight emission parameter switching instruction to the backlight control unit 306 so as to switch the parameter to be used to the backlight emission parameter corresponding to the image signal after display switching (S2403). ).

Next, the display control unit 3205 switches the image signal to be output based on the switching request signal (S2404).
The display control unit 3205 determines whether the image displayed after switching is a single display image or an external input image based on the switching request signal (S2405).
When the image displayed after the switching is an external input image (S2406: YES), the display control unit 3205 transmits the display comparison request signal and the PC identification information acquired in S2401 to the display comparison unit 3211 ( S2407).
When the image displayed after the switching is a single display image (S2406: NO), the display control unit 3205 ends the process as it is.

FIG. 23 is a flowchart illustrating an example of a flow of processing (comparison processing) of the display comparison unit 3211 when a display comparison request signal and PC identification information are received from the display control unit 3205.
First, the display comparison unit 3211 obtains the execution date (Tr) of cooperative calibration corresponding to the PC identification information from the parameter management unit 3204 (S2501).
When the execution date and time of the cooperation calibration can be acquired (S2502: YES), the process proceeds to S2503.
When the execution date / time of the cooperation calibration cannot be acquired (S2502: NO), the cooperation calibration (for the PC indicated by the PC identification information) has not been performed so far. Therefore, there is a high possibility that the external input image parameter desired by the user is not set. Therefore, in this embodiment, in such a case, the display comparison unit 3211 determines that the external input image parameter is different from the setting at the time of the previous external input image display. The display comparison unit 3211 determines that it is necessary to execute cooperative calibration, and outputs a cooperative calibration execution request signal to the calibration execution control unit 3203 (S2506).

In step S2503, the display comparison unit 3211 acquires the execution date / time (Tt) of the single unit calibration from the parameter management unit 3204.
Then, the display comparison unit 3211 compares the execution date and time of cooperative calibration acquired in S2501 with the execution date and time of single calibration acquired in S2503 (S2504). By this comparison, it is determined whether or not the external input image parameter (specifically, the parameter desired by the user) is different from the previous external input image display setting.
If the linked calibration execution date and time is earlier than the single calibration execution date and time (S2505: YES), the external input image parameter desired by the user is likely to be different from the previous setting. Therefore, in this embodiment, in such a case, the display comparison unit 3211 determines that the external input image parameter is different from the setting at the time of the previous external input image display. The display comparison unit 3211 determines that it is necessary to execute cooperative calibration, and outputs a cooperative calibration execution request signal to the calibration execution control unit 3203 (S2506).
When the execution date / time of the linked calibration is after the execution date / time of the single unit calibration (S2505: NO), the display comparison unit 3211 has the same external input image parameters as the previous external input image display settings. And the process ends.

  As described above, in this embodiment, when an external input image based on an image signal input from an external device is displayed, the external input image parameter is displayed if the external device has not been linked in the past. Is determined to be different from the setting at the time of the previous external input image display. In addition, when the last execution date and time of the linked calibration is earlier than the last execution date and time of the unit calibration, it is determined that the external input image parameter is different from the setting at the time of the previous external input image display.

  At time t4 in FIG. 20, the execution time of the cooperative calibration corresponding to the PC 111 is time t0, and the execution time of the single calibration is time tc1 (before time t0). Therefore, the display comparison unit 3211 outputs a cooperation calibration execution request signal to the calibration execution control unit 3203 based on the flowchart of FIG.

As described above, according to the present embodiment, the second display setting is the setting at the time of the previous external input image display by a simple method of comparing the execution time of the single calibration and the execution time of the linked calibration. It can be determined whether or not. Thereby, it is not necessary to measure the screen (brightness and chromaticity) as in the methods of the first and second embodiments, so that the processing load can be reduced.
In the present embodiment, the execution date and time of the cooperation calibration is stored for each PC. However, the execution date and time of the cooperation calibration may be stored without distinction for each PC. When the last execution date and time of the linked calibration is earlier than the last execution date and time of the single unit calibration, the second display setting desired by the user may be different from the setting at the time of the previous external input image display. high. Therefore, in such a case, it is determined that the second display setting is different from the setting at the time of the previous external input image display, regardless of whether the last-executed linked calibration is for the currently connected external device. May be.

210 Luminance / Chromaticity Sensors 303 and 3203 Calibration Execution Control Units 311 and 3211 Display Comparison Unit

Claims (14)

Measuring means for measuring the image displayed on the screen;
The first calibration image stored in advance is displayed, and single calibration is performed to adjust the display setting so that the measured value of the first calibration image measured by the measuring unit approaches the target value. First determining means for determining the first display setting;
A second calibration image based on a calibration image signal input from an external device is displayed, and displayed so that the measured value of the second calibration image measured by the measuring unit approaches the target value. A second determination means for determining a second display setting by executing linked calibration for adjusting the setting;
When displaying an external input image that is an image based on an image signal input from the external device, it is determined whether or not the output setting or the second display setting of the external device is different from the setting at the time of the previous external input image display. Determination means for performing,
Have
The determination means displays a second calibration image with a second display setting when displaying an external input image, and the measured value of the second calibration image measured by the measurement means and the target When the difference from the value is larger than a predetermined threshold, it is determined that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display,
The second determining means executes the linkage calibration when the determining means determines that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display. Characteristic display device. Measuring means for measuring the image displayed on the screen;
The first calibration image stored in advance is displayed, and single calibration is performed to adjust the display setting so that the measured value of the first calibration image measured by the measuring unit approaches the target value. First determining means for determining the first display setting;
A second calibration image based on a calibration image signal input from an external device is displayed, and displayed so that the measured value of the second calibration image measured by the measuring unit approaches the target value. A second determination means for determining a second display setting by executing linked calibration for adjusting the setting;
When displaying an external input image that is an image based on an image signal input from the external device, it is determined whether or not the output setting or the second display setting of the external device is different from the setting at the time of the previous external input image display. Determination means for performing,
Have
When the external input image is displayed, the determination unit displays the second calibration image with the second display setting, and is displayed with the measured value of the second calibration image and the first display setting. When the difference between the measured value of the first calibration image and the measured value of the first calibration image is larger than a predetermined threshold, it is determined that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display,
The second determining means executes the linkage calibration when the determining means determines that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display. Characteristic display device. Measuring means for measuring the image displayed on the screen;
The first calibration image stored in advance is displayed, and single calibration is performed to adjust the display setting so that the measured value of the first calibration image measured by the measuring unit approaches the target value. First determining means for determining the first display setting;
A second calibration image based on a calibration image signal input from an external device is displayed, and displayed so that the measured value of the second calibration image measured by the measuring unit approaches the target value. A second determination means for determining a second display setting by executing linked calibration for adjusting the setting;
Determination means for determining whether or not the second display setting is different from the setting at the time of the previous external input image display when displaying an external input image that is an image based on an image signal input from an external device;
Storage means for storing the past execution date and time of past single calibration and the past execution date and time of linked calibration;
Have
When the external input image is displayed, the determination unit determines that the second display setting is the previous external input image when the last execution date and time of the cooperative calibration is earlier than the last execution date and time of the unit calibration. It is determined that it is different from the display setting,
The display device according to claim 1, wherein the second determining unit performs cooperative calibration when the determining unit determines that the second display setting is different from the setting at the time of the previous external input image display. The external device that outputs the image signal to the display device can be changed,
The second determination unit performs the linked calibration and determines the second display setting for each external device,
The storage means stores the past execution date and time of cooperative calibration for each external device,
The determination unit displays the external input image based on the image signal input from the external device, and if the external device cooperative calibration has not been executed in the past, and the last execution of the cooperative calibration. The display according to claim 3, wherein when the date and time is before the last execution date and time of the single unit calibration, it is determined that the second display setting is different from the setting at the time of the previous external input image display. apparatus. A detecting unit that detects input of an image signal from the external device;
The first determination unit executes the unit calibration when a user operation for instructing execution of calibration is performed,
The second determining means includes
When the user operation is performed and an input of an image signal from the external device is detected by the detection unit, the cooperation calibration is executed,
5. The execution of the cooperative calibration is omitted when the user operation is performed and an input of an image signal from the external device is not detected by the detection unit. The display device according to any one of the above. The display device according to claim 5, wherein the second determination unit acquires a result of the detection by the detection unit in response to completion of execution of the single unit calibration. The display device according to claim 1, wherein the determination unit performs the determination according to a user operation for switching an image to be displayed to the external input image. A measurement step for measuring the image displayed on the screen;
The first calibration image stored in advance is displayed, and single calibration is performed to adjust the display setting so that the measurement value of the first calibration image measured in the measurement step approaches the target value. A first determining step for determining a first display setting;
A second calibration image based on the calibration image signal input from the external device is displayed, and the measurement value of the second calibration image measured in the measurement step is displayed so as to approach the target value. A second determination step of determining a second display setting by executing linked calibration to adjust the setting;
When displaying an external input image that is an image based on an image signal input from an external device, it is determined whether the output setting or the second display setting of the external device is different from the setting at the time of the previous external input image display A determination step for performing
Have
In the determination step, when the external input image is displayed, the second calibration image is displayed with the second display setting, and the measurement value of the second calibration image measured in the measurement step and the target When the difference from the value is larger than a predetermined threshold, it is determined that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display,
In the second determination step, when it is determined in the determination step that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display, the cooperative calibration is executed. A control method for a display device. A measurement step for measuring the image displayed on the screen;
The first calibration image stored in advance is displayed, and single calibration is performed to adjust the display setting so that the measurement value of the first calibration image measured in the measurement step approaches the target value. A first determining step for determining a first display setting;
A second calibration image based on the calibration image signal input from the external device is displayed, and the measurement value of the second calibration image measured in the measurement step is displayed so as to approach the target value. A second determination step of determining a second display setting by executing linked calibration to adjust the setting;
When displaying an external input image that is an image based on an image signal input from an external device, it is determined whether the output setting or the second display setting of the external device is different from the setting at the time of the previous external input image display A determination step for performing
Have
In the determination step, when the external input image is displayed, the second calibration image is displayed with the second display setting, and the measurement value of the second calibration image and the first display setting are displayed. When the difference between the measured value of the first calibration image and the measured value of the first calibration image is larger than a predetermined threshold, it is determined that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display,
In the second determination step, when it is determined in the determination step that the output setting of the external device or the second display setting is different from the setting at the time of the previous external input image display, the cooperative calibration is executed. A control method for a display device. A measurement step for measuring the image displayed on the screen;
The first calibration image stored in advance is displayed, and single calibration is performed to adjust the display setting so that the measurement value of the first calibration image measured in the measurement step approaches the target value. A first determining step for determining a first display setting;
A second calibration image based on the calibration image signal input from the external device is displayed, and the measurement value of the second calibration image measured in the measurement step is displayed so as to approach the target value. A second determination step of determining a second display setting by executing linked calibration to adjust the setting;
A determination step of determining whether or not the second display setting is different from the setting at the time of the previous external input image display when displaying an external input image that is an image based on an image signal input from an external device;
A storage step for storing the past execution date and time of the single unit calibration and the past execution date and time of the linked calibration;
Have
In the determination step, when the external input image is displayed, if the last execution date and time of the cooperative calibration is earlier than the last execution date and time of the unit calibration, the second display setting is the previous external input image. It is determined that it is different from the display setting,
In the second determination step, when it is determined in the determination step that the second display setting is different from the setting at the time of the previous external input image display, linked calibration is executed. Control method. The external device that outputs the image signal to the display device can be changed,
In the second determination step, for each external device, execution of cooperative calibration and determination of the second display setting are performed,
In the storing step, the past execution date and time of the cooperation calibration is stored for each external device,
In the determination step, when displaying an external input image based on an image signal input from the external device, if the external device has not been linked calibration in the past, and the last execution of the linked calibration The display according to claim 10, wherein when the date and time is before the last execution date and time of the single unit calibration, it is determined that the second display setting is different from the setting at the time of the previous external input image display. Control method of the device. A detection step of detecting input of an image signal from the external device;
In the first determination step, when a user operation instructing execution of calibration is performed, the single unit calibration is executed,
In the second determination step,
When the user operation is performed and an input of an image signal from the external device is detected by the detection step, the cooperation calibration is executed,
The execution of the cooperative calibration is omitted when the user operation is performed and an input of an image signal from the external device is not detected in the detection step. The control method of the display apparatus of any one. 13. The display device control method according to claim 12, wherein, in the second determination step, the result of the detection in the detection step is acquired in response to completion of execution of the single unit calibration. The method for controlling a display device according to claim 8, wherein in the determination step, the determination is performed in response to a user operation for switching an image to be displayed to the external input image.

Images